Efficacy of gene delivery to the brain using AAV and ultrasound depends on serotypes and brain areas.

Focused ultrasound combined with intravenously injected microbubbles (FUS) is known to non-invasively, locally, and transiently increase the permeability of the blood-brain barrier (BBB). A promising approach for non-invasive gene delivery to the brain is to administer recombinant adeno-associated viruses (AAVs) intravenously and allow them to cross the BBB at precise FUS-targeted brain regions. FUS-AAV delivery has been achieved in animal models; however, the key elements influencing, guiding, and monitoring the success of FUS-AAV delivery to the brain remain largely unknown. We systematically compared the ability of AAV1, AAV2, AAV5, AAV8, AAV9, and AAVrg to enter four specific brain regions and transduce two main cell types: neurons and astrocytes. Our results demonstrate that the AAV serotype, the extent of FUS-induced BBB permeability, and the intrinsic properties of the targeted brain tissue influence the observed biodistribution, diffusion and transduction of AAV to cells of the cerebrovasculature and brain parenchyma. Non-invasive contrast-enhanced MR imaging was found to predict the efficacy of FUS-AAV delivery. Notably, we also found that AAVs with high biodistribution to peripheral organs result in low gene delivery to the brain when combined with FUS. Gene delivery by AAV1, AAV2, AAV5, AAV8 and AAV9 was highly and selectively localized to FUS-targeted brain areas. To obtain non-invasive gene delivery to multiple brain regions with one area of FUS-BBB modulation, we combined a modified AAV2 vector harboring enhanced retrograde transport properties (AAVrg) with FUS-mediated brain delivery. This allowed for gene delivery from the FUS-targeted site to multiple connected brain regions. This study demonstrates that MR imaging can be used as a non-invasive indication of AAV delivery to the brain, and that the properties of AAV serotypes influence the efficacy of gene delivery to the brain with FUS. AAVs that have minimal peripheral biodistribution are ideal candidates for enhanced, and perhaps exclusive with future serotypes, delivery to the brain with FUS. The characterization of parameters influencing FUS-AAV delivery to the brain are critical to the design of safe and efficient gene therapies, from preclinical studies to future clinical applications.

VISTA.COMP - an engineered checkpoint receptor agonist that potently suppresses T cell-mediated immune responses.

V-domain immunoglobulin suppressor of T cell activation (VISTA) is a recently discovered immune checkpoint ligand that functions to suppress T cell activity. The therapeutic potential of activating this immune checkpoint pathway to reduce inflammatory responses remains untapped, largely due to the inability to derive agonists targeting its unknown receptor. A dimeric construct of the IgV domain of VISTA (VISTA-Fc) was shown to suppress the activation of T cells in vitro. However, this effect required its immobilization on a solid surface, suggesting that VISTA-Fc may display limited efficacy as a VISTA-receptor agonist in vivo. Herein, we have designed a stable pentameric VISTA construct (VISTA.COMP) by genetically fusing its IgV domain to the pentamerization domain from the cartilage oligomeric matrix protein (COMP). In contrast to VISTA-Fc, VISTA.COMP does not require immobilization to inhibit the proliferation of CD4+ T cells undergoing polyclonal activation. Furthermore, we show that VISTA.COMP, but not VISTA-Fc, functions as an immunosuppressive agonist in vivo capable of prolonging the survival of skin allografts in a mouse transplant model as well as rescuing mice from acute concanavalin-A-induced hepatitis. Collectively, we believe our data demonstrate that VISTA.COMP is a checkpoint receptor agonist and the first agent to our knowledge targeting the putative VISTA-receptor to suppress T cell-mediated immune responses.

RPTPα controls epithelial adherens junctions, linking E-cadherin engagement to c-Src-mediated phosphorylation of cortactin.

Epithelial junctions are fundamental determinants of tissue organization, subject to regulation by tyrosine phosphorylation. Homophilic binding of E-cadherin activates tyrosine kinases, such as Src, that control junctional integrity. Protein tyrosine phosphatases (PTPs) also contribute to cadherin-based adhesion and signaling, but little is known about their specific identity or functions at epithelial junctions. Here, we report that the receptor PTP RPTPα (human gene name PTPRA) is recruited to epithelial adherens junctions at the time of cell-cell contact, where it is in molecular proximity to E-cadherin. RPTPα is required for appropriate cadherin-dependent adhesion and for cyst architecture in three-dimensional culture. Loss of RPTPα impairs adherens junction integrity, as manifested by defective E-cadherin accumulation and peri-junctional F-actin density. These effects correlate with a role for RPTPα in cellular (c)-Src activation at sites of E-cadherin engagement. Mechanistically, RPTPα is required for appropriate tyrosine phosphorylation of cortactin, a major Src substrate and a cytoskeletal actin organizer. Expression of a phosphomimetic cortactin mutant in RPTPα-depleted cells partially rescues F-actin and E-cadherin accumulation at intercellular contacts. These findings indicate that RPTPα controls cadherin-mediated signaling by linking homophilic E-cadherin engagement to cortactin tyrosine phosphorylation through c-Src.

Protein tyrosine phosphatase α mediates profibrotic signaling in lung fibroblasts through TGF-ß responsiveness.

Fibrotic lung diseases represent a diverse group of progressive and often fatal disorders with limited treatment options. Although the pathogenesis of these conditions remains incompletely understood, receptor type protein tyrosine phosphatase α (PTP-α encoded by PTPRA) has emerged as a key regulator of fibroblast signaling. We previously reported that PTP-α regulates cellular responses to cytokines and growth factors through integrin-mediated signaling and that PTP-α promotes fibroblast expression of matrix metalloproteinase 3, a matrix-degrading proteinase linked to pulmonary fibrosis. Here, we sought to determine more directly the role of PTP-α in pulmonary fibrosis. Mice genetically deficient in PTP-α (Ptpra(-/-)) were protected from pulmonary fibrosis induced by intratracheal bleomycin, with minimal alterations in the early inflammatory response or production of TGF-ß. Ptpra(-/-) mice were also protected from pulmonary fibrosis induced by adenoviral-mediated expression of active TGF-ß1. In reciprocal bone marrow chimera experiments, the protective phenotype tracked with lung parenchymal cells but not bone marrow-derived cells. Because fibroblasts are key contributors to tissue fibrosis, we compared profibrotic responses in wild-type and Ptpra(-/-) mouse embryonic and lung fibroblasts. Ptpra(-/-) fibroblasts exhibited hyporesponsiveness to TGF-ß, manifested by diminished expression of αSMA, EDA-fibronectin, collagen 1A, and CTGF. Ptpra(-/-) fibroblasts exhibited markedly attenuated TGF-ß-induced Smad2/3 transcriptional activity. We conclude that PTP-α promotes profibrotic signaling pathways in fibroblasts through control of cellular responsiveness to TGF-ß.

Loss of function studies in mice and genetic association link receptor protein tyrosine phosphatase α to schizophrenia.

BACKGROUND: Solid evidence links schizophrenia (SZ) susceptibility to neurodevelopmental processes involving tyrosine phosphorylation-mediated signaling. Mouse studies implicate the Ptpra gene, encoding protein tyrosine phosphatase RPTPα, in the control of radial neuronal migration, cortical cytoarchitecture, and oligodendrocyte differentiation. The human gene encoding RPTPα, PTPRA, maps to a chromosomal region (20p13) associated with susceptibility to psychotic illness. METHODS: We characterized neurobehavioral parameters, as well as gene expression in the central nervous system, of mice with a null mutation in the Ptpra gene. We searched for genetic association between polymorphisms in PTPRA and schizophrenia risk (two independent cohorts, 1420 cases and 1377 controls), and we monitored PTPRA expression in prefrontal dorsolateral cortex of SZ patients (35 cases, 2 control groups of 35 cases). RESULTS: We found that Ptpra⁻/⁻ mice reproduce neurobehavioral endophenotypes of human SZ: sensitization to methamphetamine-induced hyperactivity, defective sensorimotor gating, and defective habituation to a startle response. Ptpra loss of function also leads to reduced expression of multiple myelination genes, mimicking the hypomyelination-associated changes in gene expression observed in postmortem patient brains. We further report that a polymorphism at the PTPRA locus is genetically associated with SZ, and that PTPRA mRNA levels are reduced in postmortem dorsolateral prefrontal cortex of subjects with SZ. CONCLUSIONS: The implication of this well-studied signaling protein in SZ risk and endophenotype manifestation provides novel entry points into the etiopathology of this disease.

Activation of c-Src and Fyn kinases by protein-tyrosine phosphatase RPTPalpha is substrate-specific and compatible with lipid raft localization.

Src family tyrosine kinases (SFKs) function in multiple signaling pathways, raising the question of how appropriate regulation and substrate choice are achieved. SFK activity is modulated by several protein-tyrosine phosphatases, among which RPTPalpha and SHP2 are the best established. We studied how RPTPalpha affects substrate specificity and regulation of c-Src and Fyn in response to epidermal growth factor and platelet-derived growth factor. We find that RPTPalpha, in a growth factor-specific manner, directs the specificity of these kinases toward a specific subset of SFK substrates, particularly the focal adhesion protein Paxillin and the lipid raft scaffolding protein Cbp/PAG. A significant fraction of RPTPalpha is present in lipid rafts, where its targets Fyn and Cbp/PAG reside, and growth factor-mediated SFK activation within this compartment is strictly dependent on RPTPalpha. Forced concentration of RPTPalpha into lipid rafts is compatible with activation of Fyn. Finally, RPTPalpha-induced phosphorylation of Paxillin and Cbp/PAG induces recruitment of the SFK inhibitory kinase Csk, indicative of negative feedback loops limiting SFK activation by RPTPalpha. Our findings indicate that individual SFK-controlling PTPs play important and specific roles in dictating SFK substrate specificity and regulatory mechanism.

Receptor protein tyrosine phosphatase gamma is a marker for pyramidal cells and sensory neurons in the nervous system and is not necessary for normal development.

In order to gain insight into the biological role of receptor protein tyrosine phosphatase gamma (RPTPgamma), we have generated RPTPgamma-null mice. RPTPgamma was disrupted by insertion of the beta-galactosidase gene under the control of the RPTPgamma promoter. As the RPTPgamma-null mice did not exhibit any obvious phenotype, we made use of these mice to study RPTPgamma expression and thus shed light on potential biological functions of this phosphatase. Inspection of mouse embryos shows that RPTPgamma is expressed in a variety of tissues during embryogenesis. RPTPgamma is expressed in both embryonic and adult brains. Specifically, we detected RPTPgamma expression in cortical layers II and V and in the stratum pyramidale of the hippocampus, indicating that RPTPgamma is a marker for pyramidal neurons. Mixed primary culture of glial cells showed a lack of expression of RPTPgamma in astrocytes and a low expression of RPTPgamma in oligodendrocytes and in microglia. Interestingly, RPTPgamma expression was detected in all sensory organs, including the ear, nose, tongue, eye, and vibrissa follicles, suggesting a potential role of RPTPgamma in sensory neurons. An initial behavioral analysis showed minor changes in the RPTPgamma-null mice.